Superwide pouch type secondary battery with double tabs

ABSTRACT

Provided is a superwide pouch type secondary battery comprising an electrode assembly including a cathode plate, an anode plate, and a separator; a pouch surrounding the electrode assembly; and electrode tabs connected to both ends of the electrode assembly and protruding outward of the pouch, wherein the electrode tabs connected to the both ends of the electrode assembly include one or more cathode tabs and anode tabs, respectively, and width of battery cell is more than 4 times longer than height of battery cell such that loading efficiency of the pouch type secondary battery into a vehicle and an energy density may be improved without increasing an internal electrode.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority under 35 U.S.C. § 119 to Korean PatentApplication No. 10-2019-0043771, filed on Apr. 15, 2019, and No.10-2019-0157980, filed on Dec. 2, 2019, in the Korean IntellectualProperty Office, the disclosure of which is incorporated herein byreference in its entirety.

TECHNICAL FIELD

The following disclosure relates to a pouch type secondary battery, andmore particularly, to a superwide pouch type secondary battery in whicha width between electrode tabs is wide.

BACKGROUND

A secondary battery has been prominent as a power source of an electricvehicle, a hybrid electric vehicle, and the like, that have beenproposed as a solution for air pollution of an existing gasolinevehicle, a diesel vehicle, or the like, that uses a fossil fuel.

Meanwhile, in order to load the secondary battery into the vehicle, ithas been required to improve an energy density and solve a spaceconstraint. Particularly, as a battery pack is disposed on a floor ofthe vehicle for space efficiency, a wide battery cell whose length atedges between electrode tabs is much larger than that at edges where theelectrode tabs are positioned has been required.

However, in a wide or superwide battery cell, a length between theelectrode tabs is increased, such that an internal resistance of thebattery cell is increased, resulting in an increase in powerconsumption, and a temperature difference is large for each region ofthe battery cell, resulting in a decrease in performance of the batterycell and a lifespan of the battery. Therefore, a technology capable ofdecreasing the internal resistance of the battery cell and implementinga large width of the battery cell has been demanded.

SUMMARY

An embodiment of the present invention is directed to providing asuperwide pouch type secondary battery capable of having a superwidewidth implemented without increasing an internal resistance of a batterycell.

Further, an embodiment of the present invention is directed to providingan electrode tab structure and a connection structure between anelectrode assembly and an electrode tab that are required in designing asuperwide pouch type secondary battery.

In one general aspect, a pouch type secondary battery includes: anelectrode assembly including a cathode plate, an anode plate, and aseparator; a pouch surrounding the electrode assembly; and electrodetabs connected to both ends of the electrode assembly and protrudingoutward of the pouch, wherein the electrode tabs connected to the bothends of the electrode assembly include two or more cathode tabs andanode tabs, respectively, and Wc/Hc>4 in which Hc is a length of abattery cell at edges in a first direction of the battery cell to whichthe electrode tabs are connected and Wc is a length of the battery cellat edges in a second direction of the battery cell except for protrusionlengths of the electrode tabs, the second direction being perpendicularto the first direction. In addition, preferably, Wc/Hc>5 and morepreferably, Wc/Hc>7.

Both ends of edges of the cathode tab and the anode tab in the seconddirection may have a shape in which thicknesses thereof are graduallydecreased in the first direction.

Sealing films for protecting the electrode tabs at the time of sealingthe pouch may be disposed at connected portions to which the electrodetabs are connected, in a form in which the sealing films surround theelectrode tabs, and the sealing films may be disposed in a form in whichthe sealing films surround the cathode tab and the anode tab,respectively.

The length of the battery cell at the edge of the second direction maybe 300 mm or more, and the length of the battery cell at the edge of thefirst direction may be 70 mm or more.

0.3 mm<t1<1.5 mm and 1.0<t1/t2<2.0 in which t1 is a thickness of thecathode tab and t2 is a thickness of the annode tab.

0.3<(Wt1+Wt2)/Hc<0.6 in which Wt1 is a width of the cathode tab and Wt2is a width of the anode tab.

0.4<(Ws1+Ws2)/Hc<1.2 in which Ws1 is a width of a cathode tab sealingfilm surrounding the cathode tab and Ws2 is a width of an anode tabsealing film surrounding the anode tab.

0.08<Wsg/(Ws1+Ws2) 0.32 in which Wsg is a distance between one end ofthe cathode tab sealing film surrounding the cathode tab and one end ofthe anode tab sealing film surrounding the anode tab.

A bent portion surrounding the electrode assembly may formed at one edgeof the pouch, and a sealing portion may be formed at the other edge ofthe pouch by bonding both ends of the pouch to each other.

In another general aspect, a battery module includes the pouch typesecondary battery described above.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of a pouch type secondary battery accordingto the present invention.

FIG. 2 is a plan view of the pouch type secondary battery according tothe present invention.

FIGS. 3A and 3B are plan views of a general pouch type secondary batteryand a superwide pouch type secondary battery according to ComparativeExample, respectively.

FIG. 4 is an enlarged view of part A of FIG. 1.

FIG. 5 is a front view of the pouch type secondary battery according tothe present invention as viewed from an electrode tab direction.

FIG. 6 is a cross-sectional view taken along line X-X′ of FIG. 2.

DETAILED DESCRIPTION OF EMBODIMENTS

Advantages and features of exemplary embodiments of the presentinvention and a method of accomplishing them will become apparent fromthe following description of exemplary embodiments with reference to theaccompanying drawings. However, the present invention is not limited toexemplary embodiments to be described later, but may be implemented invarious different forms, these exemplary embodiments will be providedonly in order to make the disclosure of the present invention completeand allow those skilled in the art to completely recognize the scope ofthe present invention, and the present invention will be defined by thescope of the claims. Throughout the specification, like referencenumerals denote like elements.

In describing exemplary embodiments of the present invention, when it isdetermined that a detailed description for the known functions orcomponents may unnecessarily obscure the gist of the present invention,the detailed description will be omitted. Further, terms to be describedlater are defined in consideration of functions in exemplary embodimentsof the present invention and may be construed in different ways byintentions of users and operators. Therefore, these terms should bedefined on the basis of the contents throughout the specification.

A battery module according to the present invention will be describedwith reference to the accompanying drawings.

FIGS. 1 and 2 are, respectively, a perspective view and a plan view of apouch type secondary battery 1000 according to the present invention.Referring to FIGS. 1 and 2, the pouch type secondary battery 1000according to the present invention includes a battery cell 100 in whichan electrode assembly 110 including a cathode plate, an anode plate, anda separator is surrounded by a pouch 120; and electrode tabs 200connected to both ends of the battery cell 100. Here, Wc/Hc>4 in whichHc is a length of the battery cell 100 at edges in a first direction ofthe battery cell 100 to which the electrode tabs 200 are connected andWc is a length of the battery cell 100 at edges in a second direction ofthe battery cell 100 except for protrusion lengths of the electrodetabs, the second direction being perpendicular to the first direction.In addition, the electrode tabs 200 of both ends include two or morecathode tabs 210 and anode tabs 220, respectively. Preferably, a lengthof the battery cell 100 at edges in a second direction of the batterycell 100 may be elongated to Wc/Hc>5, or more preferably Wc/Hc>7.

A general pouch type secondary battery has a width Wc corresponding to alength of approximately 300 mm, and may be usually designed to have along width corresponding to a length up to about 600 mm. However, in thepresent invention, in order to implement maximum space efficiency and anoptimum energy density in disposing a secondary battery on a floor of avehicle, a superwide pouch type secondary battery having a low height Hcand a long width Wc capable of corresponding to a width of the vehicleis devised. In the present invention, a superwide secondary battery inwhich Wc/Hc>4 by designing the length (height) Hc at the edges in thefirst direction of the battery cell to which the electrode tabs 200 areconnected to be in a range of 60 to 80 mm and designing the width We tobe larger than 240 mm is proposed. As another exemplary embodiment, asuperwide secondary battery in which Wc/Hc>4 by designing the length(height) Hc at the edges in the first direction of the battery cell tobe in a range of 70 mm or more and designing the width Wc to be 300 mmor more is proposed. As still another exemplary embodiment, a superwidesecondary battery in which Wc/Hc>7 boy designing the length (height) Hcat the edges in the first direction of the battery cell to be in a rangeof 90 to 110 mm and designing the width Wc to be 630 mm or more isproposed. High capacity of the battery cells may be implemented byelongation of a length of the battery cell 100 at edges in a seconddirection of the battery cell 100, but a length between the electrodetabs is increased, such that an internal resistance of the battery celland heat generation are increased. Therefore, problem of increasing ofinternal resistance and heat generation should be resolved.

In installing a battery pack on a lower portion of the vehicle, thebattery pack may be configured by arranging general secondary batterieshaving a width that is not long in a length direction so as tocorrespond to a width of the vehicle. However, in this case, the numberof battery cells is increased, such that problems such as an increase inthe number of components, a decrease in productivity, and a costincrease occur, and there is a limitation in implementing a highcapacity of the battery cells. On the other hand, in the presentinvention, as described above, the superwide pouch type secondarybattery capable of corresponding to the width of the vehicle isdesigned, such that the number of components may be decreased,productivity may be improved, a cost may be decreased, and an energydensity may be improved using a superwide electrode assembly 110.

Meanwhile, a length of the electrode assembly 110 is increased, suchthat a conduction path between the electrode tabs 200 is also increased.Therefore, an internal resistance of the battery cell 100 is increased,such that power consumption is generated and an amount of heat generatedin the battery cell 100 is increased. The present invention proposes amethod of connecting two or more cathode tabs 210 and anode tabs 220 toboth ends of superwide pouch type secondary battery 1000 as analternative to solve the problem as described above, and it ispreferable to connect one cathode tab 210 and one anode tab 220 to eachof the both ends of the superwide pouch type secondary battery 1000.

FIG. 3A illustrates a pouch type secondary battery having a generalwidth in which only one cathode tab or anode tab are connected to bothends as Comparative Example of the present invention. FIG. 3Billustrates a superwide pouch type secondary battery in which only onecathode tab or anode tab are connected to both ends as ComparativeExample of the present invention.

An effective method of decreasing the internal resistance is to increasethe number and a thickness of electrode tabs, but when the number andthe thickness of electrode tabs are increased, a sealing problem mayoccur at connected portions 130 connected to the battery cell 100. Inorder to solve such a problem, the present invention proposescross-sectional shapes of the electrode tabs and a method of disposingsealing films 131 and 132 on connected portions 130 of the electrodetabs as a solution. FIG. 4 is an enlarged view of part A of FIG. 1cathode tab sealing film 131 and an anode tab sealing film 132 aredisposed, respectively, on the connected portions 130 to which thecathode tab 210 and the anode tab 220 are connected, and both ends ofedges of the cathode tab 210 and the anode tab 220 in the seconddirection have a shape in which thicknesses thereof are graduallydecreased in the first direction. That is, at the connected portions130, the cathode tab 210 and the anode tab 220 are surrounded by thesealing films 131 and 132, respectively, and a cathode tab edge 211 andan anode tab edge 221 positioned at sealing portions are formed to havegradually decreased thicknesses, such that sealing performance isexcellent even though thicknesses of electrode tabs are increased.

FIG. 5 is a view of the pouch type secondary battery according to thepresent invention as viewed from an electrode tab direction in order todescribe a design specification according to an exemplary embodiment.Referring to FIG. 5, as described above, in the superwide pouch typesecondary battery according to present invention, one cathode tab 210and one anode tab 220 are connected to each of both ends of the batterycell, and the cathode tab 210 and the anode tab 220 are sealed by thepouch 120 in a state where they are surrounded by the cathode tabsealing film 131 and the anode tab sealing film, respectively.

Meanwhile, when a thickness of the cathode tab 210 is t1 and a thicknessof the anode tab 220 is t2, it is preferable that 0.3 mm<t1<1.5 mm. In acase where the thickness of the cathode tab 210 is 0.3 mm or less, aninternal resistance decrease effect is deteriorated, and in a case wherethe thickness of the cathode tab 210 is 1.5 mm or more, sealingperformance is weakened. In addition, a thickness ratio between thecathode tab 210 and the anode tab 220 of the general pouch typesecondary battery is 2 or more, while in the superwide pouch typesecondary battery according to the present invention, it is preferableto set t1/t2 so that 1.0<t1/t2<2.0 by relatively decreasing thethickness of the cathode tab 210. Sealing performance may be improvedwithout significantly increasing the internal resistance by setting thethickness of the cathode tab 210 to be small. Preferably, t1 and t1/t2may be set so that 0.8 mm<t1 <1.2 mm and 1.4 <t1/t2<1.8, respectively,and more preferably, t1/t2 may be set so that 1.6<t1/t2<1.7.

Since a plurality of electrode tabs are connected to both ends of thebattery cell, widths of the electrode tabs, widths of the sealing films,an insulation distance, and the like, need to be set in the ranges inwhich the above conditions are satisfied in order to secure sealingperformance of the cathode tab 210 and the anode tab 220 that becomethick while securing a minimum insulation distance between the cathodetab 210 and the anode tab 220.

It is preferable to set (wt1+Wt2)/Hc so that 0.3<(Wt1+Wt2)/Hc<0.6 inwhich Wt1 is a width of the cathode tab 210 and Wt2 is a width of theanode tab 220, and it is more preferable set (wt1+Wt2)/Hc so that0.4<(Wt1+Wt2)/Hc<0.6. In a case where the sum of the widths of thecathode tab 210 and the anode tab 220 is lower than the range describedabove, an increase in an internal resistance may not be prevented, andin a case where the sum of the widths of the cathode tab 210 and theanode tab 220 is higher than the range described above, it is difficultto secure sufficient sealing performance. In addition, it is preferableto set (Ws1+Ws2)/Hc so that 0.7<(Ws1−Ws2)/Hc<1.2 in which Ws1 is a widthof the cathode tab sealing film 131 surrounding the cathode tab 210 andWs2 is a width of the anode tab sealing film 132 surrounding the anodetab 220. In a case where (Ws1+Ws2)/Hc is smaller than 0.7, the electrodetab may not be sufficiently protected, and in a case where (Ws1+Ws2)/Hcis larger than 1.2, it is difficult to perform pouch sealing. It is morepreferable to set (Ws1+Ws2)/Hc so that 0.7<(Ws1+Ws2)/Hc<0.9.

Meanwhile, in order to secure the minimum insulation distance betweenthe cathode tab 210 and the anode tab 220, it is preferable to setWtg/Hc so that Wtg/Hc>0.1 in which Wtg is a distance between the cathodetab 210 and the anode tab 220, and it is more preferable to set Wtg/Hcso that Wtg/Hc>0.12. In addition, is preferable to set Wsg/(Ws1+Ws2) sothat 0.08<Wsg/(Ws1+Ws2)<0.32 in which Wsg is distance between one end ofthe cathode tab sealing film 131 and one end of the anode tab sealingfilm 132, and is more preferable to set Wsg/(Ws1+Ws2) so that0.12<Wsg/(Ws1+Ws2)<0.30.

Table 1 illustrates exemplary experiment results for comparing arelationship between an increase in widths, thicknesses of tabs, and thenumber of tabs, and is a table in which internal resistances of batterycells of superwide pouch type secondary batteries (Comparative Examples)in which only one cathode tab or one anode tab is connected andsuperwide pouch type secondary batteries (Embodiment Examples) in whichone cathode tab 210 and one anode tab 220 are connected to each of bothends are compared with each other while increasing a ratio betweenwidths on the basis of a reference model. Comparative Example 1 is anexample of making thicknesses of a cathode tab and an anode tab equal tothose or a reference pouch type secondary battery, and ComparativeExample 2 is an example of increasing thicknesses of a cathode tab andan anode tab in order to decrease an internal resistance. EmbodimentExample 1 is an example of installing two electrode tabs at each of bothends, and Embodiment Example 2 is an example of increasing widths ofelectrode tabs in order to increase cross-sectional areas of theelectrode tabs.

TABLE 1 Comparative Comparative Embodiment Embodiment Unit ReferenceExample 1 Example 2 Example 1 Example 2 Battery Width (Wc) mm 530 800800 800 800 Cell Height (Hc) mm 100 100 100 100 100 Electrode Number 1 11 2 2 Tab Width (Wt) mm 45 45 45 22.5 27.6 22.5 27.6 Thickness mm 0.40.4 1 1 1 (t1) of Cathode Tab Thickness mm 0.2 0.2 0.6 0.6 0.6 (t2) ofAnode Tab Internal Resistance mΩ 0.88 1.32 1.27 0.89 0.89 InternalResistance mΩ — 0.44 0.39 0.01 0.01 Difference

As compared with the reference pouch type secondary battery, inComparative Example 1, a width of a battery cell was increased, suchthat an internal resistance was increased by 0.44 mΩ, and in ComparativeExample 2, even though thicknesses of a cathode tab and an anode tabwere increased in order to decrease an internal resistance, the internalresistance was still increased by 0.39 mΩ. On the other hand, inEmbodiment Example 1 in which two electrode tabs are installed at eachof both ends, an increase amount in an internal resistance was 0.1 mΩ,which does not have a significant difference from an increase amount inan internal resistance of the model, and in Embodiment Example 2 inwhich widths of electrode tabs are increased, an increase amount in aninternal resistance did not have a significant difference from anincrease amount in an internal resistance of Embodiment Example 1.Therefore, it may be seen that the most effective method of decreasingthe internal resistance is to make the number of electrode tabs two ormore and increase the thicknesses of the electrode tabs.

In addition, since a width of the battery cell 100 is increased, it isnecessary to improve cooling efficiency of the battery cell 100. To thisend, the present invention proposes a method in which the pouch 120surrounds the electrode assembly 110 on three sides. FIG. 6 is across-sectional view taken along line X-X′ of FIG. 2. Referring to FIG.6, the pouch 120 according to the present invention surrounds theelectrode assembly 110 in which the cathode plate, the anode plate, andthe separator are stacked, a bent portion 121 surrounding the electrodeassembly 110 is formed at one edge of the pouch, and a sealing portionis formed at the other edge of the pouch by bonding both ends of thepouch to each other. That is, the sealing portion 122 of the pouch isformed at only one edge of the pouch, such that three sides surround theelectrode assembly 110 in a plane shape without having sealing portions,and an area at which a separate cooling member comes intosurface-contact with the electrode assembly 110 may be increased toimprove cooling efficiency.

According to the configuration as described above, the pouch typesecondary battery according to the present invention may implementmaximum space efficiency and an optimal energy density, and may beloaded into the vehicle.

In addition, in the pouch type secondary battery according to thepresent invention, the superwide width capable of corresponding to thewidth of the vehicle is implemented, such that the number of componentsof the battery pack may be decreased, productivity may be improved, acost may be decreased, and an energy density may be improved using asuperwide electrode assembly.

Further, the superwide width may be implemented without increasing theinternal resistance by suggesting implementing method to multipleelectrode tabs in relatively short edge, and even though the number andthicknesses of electrode tabs are increased, sealing performance at theconnected portions may be improved.

In addition, the sealing portion of the pouch is formed at one edge ofthe pouch to increase the area at which the separate cooling membercomes into surface-contact with the electrode assembly, such that thecooling efficiency may be improved.

The technical spirit of the present invention is not to be construed asbeing limited to the exemplary embodiment described above. The presentinvention may be applied to various fields and may be variously modifiedby those skilled in the art without departing from the scope of thepresent invention claimed in the claims. Therefore, it is obvious tothose skilled in the art that these alterations and modifications fallin the scope of the present invention.

DETAILED DESCRIPTION OF MAIN ELEMENTS

1000: pouch type secondary battery according to the present invention

100: battery cell

110: electrode assembly

120: pouch

121: bent portion

122: sealing portion

130: connected portion

131: cathode tab sealing film

132: anode tab sealing film

200: electrode tab

210: cathode tab

211: cathode tab edge

220: anode tab

221: anode tab edge

What is claimed is:
 1. A pouch type secondary battery comprising: anelectrode assembly including a cathode plate, an anode plate, and aseparator; a pouch surrounding the electrode assembly; and electrodetabs connected to both ends of the electrode assembly and protrudingoutward of the pouch, wherein the electrode tabs connected to the bothends of the electrode assembly include two or more cathode tabs andanode tabs, respectively, and Wc/Hc>4 in which Hc is a length of abattery cell at edges in a first direction of the battery cell to whichthe electrode tabs are connected and Wc is a length of the battery cellat edges in a second direction of the battery cell except for protrusionlengths of the electrode tabs, the second direction being perpendicularto the first direction.
 2. The pouch type secondary battery of claim 1,wherein both ends of edges of the cathode tab and the anode tab in thesecond direction have a shape in which thicknesses thereof are graduallydecreased in the first direction.
 3. The pouch type secondary battery ofclaim 2, wherein sealing films for protecting the electrode tabs at thetime of sealing the pouch are disposed at connected portions to whichthe electrode tabs are connected, in a form in which the sealing filmssurround the electrode tabs, and the sealing films are disposed in aform in which the sealing films surround the cathode tab and the anodetab, respectively.
 4. The pouch type secondary battery of claim 1,wherein the length of the battery cell at the edge of the seconddirection is 300 mm or more, and the length of the battery cell at theedge of the first direction is 70 mm or more.
 5. The pouch typesecondary battery of claim 1, wherein 0.3 mm<t1<1.5 mm and 1.0<t1/t2<2.0in which t1 is a thickness of the cathode tab and t2 is a thickness ofthe anode tab.
 6. The pouch type secondary battery of claim 5, wherein0.3<(Wt1+Wt2)/Hc<0.6 in which Wt1 is a width of the cathode tab and Wt2is a width or the anode tab.
 7. The pouch type secondary battery ofclaim 6, wherein 0.4<(Ws1+Ws2)/Hc<1.2 in which Ws1 is a width of acathode tab sealing film surrounding the cathode tab and Ws2 is a widthof an anode tab sealing film surrounding the anode tab.
 8. The pouchtype secondary battery of claim 7 wherein 0.08<Wsg/(Ws1+Ws2)<0.32 inwhich Wsg is a distance between one end of the cathode tab sealing filmsurrounding the cathode tab and one end of the anode tab sealing filmsurrounding the anode tab.
 9. The pouch type secondary battery of claim1, wherein a bent portion surrounding the electrode assembly is formedat one edge of the pouch, and a sealing portion is formed at the otheredge of the pouch by bonding both ends of the pouch to each other. 10.The pouch type secondary battery of claim 1, Wc/Hc>5 in which Hc is alength of a battery cell at edges in a first direction of the batterycell to which the electrode tabs are connected and Wc is a length of thebattery cell at edges in a second direction of the battery cell exceptfor protrusion lengths of the electrode tabs, the second direction beingperpendicular the first direction.
 11. The pouch type secondary batteryof claim 1, Wc/Hc>7 in which Hc is a length of a battery cell at edgesin a first direction of the battery cell to which the electrode tabs areconnected and Wc is a length of the battery cell at edges in a seconddirection of the battery cell except for protrusion lengths of theelectrode tabs, the second direction being perpendicular to the firstdirection.
 12. A battery module comprising the pouch type secondarybattery claim 1.